English

Non-local Dirichlet Forms and Symmetric Jump Processes

Probability 2007-05-23 v1 Analysis of PDEs

Abstract

We consider the symmetric non-local Dirichlet form (E,F)(E, F) given by E(f,f)=RdRd(f(y)f(x))2J(x,y)dxdy E (f,f)=\int_{R^d} \int_{R^d} (f(y)-f(x))^2 J(x,y) dx dy with FF the closure of the set of C1C^1 functions on RdR^d with compact support with respect to E1E_1, where E1(f,f):=E(f,f)+Rdf(x)2dxE_1 (f, f):=E (f, f)+\int_{R^d} f(x)^2 dx, and where the jump kernel JJ satisfies κ1yxdαJ(x,y)κ2yxdβ \kappa_1|y-x|^{-d-\alpha} \leq J(x,y) \leq \kappa_2|y-x|^{-d-\beta} for 0<α<β<2,xy<10<\alpha< \beta <2, |x-y|<1. This assumption allows the corresponding jump process to have jump intensities whose size depends on the position of the process and the direction of the jump. We prove upper and lower estimates on the heat kernel. We construct a strong Markov process corresponding to (E,F)(E, F). We prove a parabolic Harnack inequality for nonnegative functions that solve the heat equation with respect to EE. Finally we construct an example where the corresponding harmonic functions need not be continuous.

Cite

@article{arxiv.math/0609842,
  title  = {Non-local Dirichlet Forms and Symmetric Jump Processes},
  author = {M. T. Barlow and R. F. Bass and Z. -Q. Chen. and M. Kassmann},
  journal= {arXiv preprint arXiv:math/0609842},
  year   = {2007}
}